Methods and apparatus for providing a secure overlay network between clouds

ABSTRACT

A process capable of automatically establishing a secure overlay network (“SON”) across different clouds is disclosed. The process, in one aspect, receives a first request from a first node in a first cloud for establishing a SON. After receiving a second request for connecting to the SON from a second node in a second cloud, a first connection is established connecting between the first node and the second node utilizing a network security protocol such as Internet Protocol Security (“IPSec”). After receiving a third request for connecting to the SON from a third node in a third cloud, a second connection is used to connect between the first node and the third node. A third connection is used to connect between the second node and the third node. Each subsequent request for connecting to the SON from a new node results in new connections between the new node and each existing node in the SON forming a full-mesh.

FIELD

The exemplary embodiment(s) of the present invention relates tocommunication networks. More specifically, the disclosed embodiment(s)of the present application relates to communication between clouds.

BACKGROUND

In today's modern computing world, more and more components are beingvirtualized to save capital expenditure for various entities, such ascompanies, public institutions, government agencies, individuals, andthe like. To further reduce expenditure and conserve resources, entitiesare gradually allowing third party providers to maintain cloudinfrastructure for hosting subscribers' virtual as well as physicalcomponents. A cloud or cloud provider, also known as cloud computing ora cluster of servers, becomes viable when entities need to increasetheir computing capacity or new features without investing insubstantial amount of new infrastructure, personnel, hardware and/orsoftware. It should be noted that typical third party or public cloudinfrastructure providers includes, but not limited to, Amazon™, Google™,RackSpace™, and the like. For example, a cloud provider supplies cloudcomputing which can be subscription-based or pay-per-use serviceaccessible over the Internet.

While some components or devices can be virtualized, others are stillphysical machines with hardware components placed in the vicinity ofpremise(s), such as laboratories, testing sites, demo sites,manufacturing facilities, and so forth. However, a problem associatedwith devices and/or components situated in various clouds is that aseamless communication between such components located in differentclouds is difficult to achieve. A conventional approach to resolve thisproblem typically requires cumbersome information technology (“IT”)steps requiring skilled IT administrator(s) to setup each directconnection. For example, the steps may require a skilled IT person tosetup communication between devices located in different cloudlocations. The manual steps may involve in opening firewalls for certainprivate clouds and additional scripts may be needed to setup certainconnections or links.

SUMMARY

A secure overlay network (“SON”), in one embodiment, can beautomatically established to enhance device communication betweendifferent clouds located in different locations. For example, a processable to create an overlay network receives a first request from adashboard managed by an orchestrator for establishing a SON. SON iscapable of facilitating a point-to-point connection between nodesresiding in different clouds. A node can be a cluster of network devicesor components, such as routers, hosts, switches, servers, database, andthe like. After receiving a second request for connecting to the SONfrom a second node of a second cloud, a first connection is establishedbetween the first node and the second node using network securityprotocol such as Internet Protocol Security (“IPSec”). After receiving athird request for connecting to the SON from a third node in a thirdcloud, a second connection is established to connect the first node tothe third node. A third connection is created to connect the second nodeto the third node.

Additional features and benefits of the exemplary embodiment(s) of thepresent invention will become apparent from the detailed description,figures and claims set forth below.

BRIEF DESCRIPTION OF THE DRAWINGS

The exemplary embodiment(s) of the present invention will be understoodmore fully from the detailed description given below and from theaccompanying drawings of various embodiments of the invention, which,however, should not be taken to limit the invention to the specificembodiments, but are for explanation and understanding only.

FIG. 1 is a block diagram illustrating a network having an orchestratorable to manage and launch a secure overlay network (“SON”) betweenclouds in accordance with one embodiment of the present invention;

FIG. 2 is a block diagram illustrating an exemplary orchestrator havinga dashboard capable of managing a SON in accordance with one embodimentof the present invention;

FIG. 3 is a block diagram illustrating an exemplary dashboard able tofacilitate launch and manage a SON in accordance with one embodiment ofthe present invention;

FIG. 4 is a block logic diagram illustrating exemplary clouds connectedby a SON in accordance with one embodiment of the present invention;

FIG. 5 is a block diagram illustrating an exemplary networkconfiguration having multiple clouds coupled with a SON in accordancewith one embodiment of the present invention;

FIG. 6 is a logic block diagram illustrating an exemplary process ofestablishing a SON across cloud boundaries in accordance with oneembodiment of the present invention; and

FIG. 7 is a flowchart illustrating an exemplary process of establishinga SON coupling multiple clouds together in accordance with oneembodiment of the present invention.

DETAILED DESCRIPTION

Exemplary embodiment(s) of the present invention is described herein inthe context of a method, device, and apparatus for establishing andmanaging a secure overlay network (“SON”) over a virtual network (“VN”)containing multiple clouds.

Those of ordinary skills in the art will realize that the followingdetailed description of the exemplary embodiment(s) is illustrative onlyand is not intended to be in any way limiting. Other embodiments willreadily suggest themselves to such skilled persons having the benefit ofthis disclosure. Reference will now be made in detail to implementationsof the exemplary embodiment(s) as illustrated in the accompanyingdrawings. The same reference indicators will be used throughout thedrawings and the following detailed description to refer to the same orlike parts.

In the interest of clarity, not all of the routine features of theimplementations described herein are shown and described. It will, ofcourse, be understood that in the development of any such actualimplementation, numerous implementation-specific decisions may be madein order to achieve the developer's specific goals, such as compliancewith application- and business-related constraints, and that thesespecific goals will vary from one implementation to another and from onedeveloper to another. Moreover, it will be understood that such adevelopment effort might be complex and time-consuming, but wouldnevertheless be a routine undertaking of engineering for those ofordinary skills in the art having the benefit of embodiment(s) of thisdisclosure.

Various embodiments of the present invention illustrated in the drawingsmay not be drawn to scale. Rather, the dimensions of the variousfeatures may be expanded or reduced for clarity. In addition, some ofthe drawings may be simplified for clarity. Thus, the drawings may notdepict all of the components of a given apparatus (e.g., device) ormethod.

Unless otherwise defined, all terms (including technical and scientificterms) used herein have the same meaning as commonly understood by oneof ordinary skills in the art to which the exemplary embodiment(s)belongs. It will be further understood that terms, such as those definedin commonly used dictionaries, should be interpreted as having a meaningthat is consistent with their meaning in the context of the relevant artand this exemplary embodiment(s) of the disclosure.

As used herein, the singular forms “a”, “an” and “the” are intended toinclude the plural forms as well, unless the context clearly indicatesotherwise. It will be further understood that the terms “comprises”and/or “comprising,” when used in this specification, specify thepresence of stated features, integers, steps, operations, elements,and/or components, but do not preclude the presence or addition of oneor more other features, integers, steps, operations, elements,components, and/or groups thereof. The term “and/or” includes any andall combinations of one or more of the associated listed items.

The term “system” is used generically herein to describe any number ofcomponents, elements, sub-systems, devices, packet switch elements,packet switches, access switches, routers, networks, computer and/orcommunication devices or mechanisms, or combinations of componentsthereof. The term “computer” includes a processor, memory, and busescapable of executing instruction wherein the computer refers to one or acluster of computers, personal computers, workstations, mainframes, orcombinations of computers thereof.

IP communication network, IP network, or communication network means anytype of network having an access network able to transmit data in theform of packets or cells, such as ATM (Asynchronous Transfer Mode) type,on a transport medium, for example, the TCP/IP or UDP/IP type. ATM cellsare the result of decomposition (or segmentation) of packets of data, IPtype, and those packets (here IP packets) comprise an IP header, aheader specific to the transport medium (for example UDP or TCP) andpayload data. The IP network may also include a satellite network, aDVB-RCS (Digital Video Broadcasting-Return Channel System) network,providing Internet access via satellite, or an SDMB (Satellite DigitalMultimedia Broadcast) network, a terrestrial network, a cable (xDSL)network or a mobile or cellular network (GPRS/EDGE, or UMTS (whereapplicable of the MBMS (Multimedia Broadcast/Multicast Services) type,or the evolution of the UMTS known as LTE (Long Term Evolution), orDVB-H (Digital Video Broadcasting-Handhelds)), or a hybrid (satelliteand terrestrial) network.

One embodiment of the present application discloses a mechanism creatinga SON to provide point-to-point connections between various nodes orhosts situated in different clouds. The mechanism or process, in oneaspect, is able to receive a first request from a dashboard requesting aSON. Note that the SON is capable of facilitating a point-to-pointconnection between nodes residing in different clouds. A node can be acluster of network devices or components, such as routers, hosts,switches, servers, database, and the like.

After receiving a second request for connecting to the SON from a secondnode of a second cloud, a first connection is established between thefirst node in first cloud and the second node in second cloud usingnetwork security protocol such as IPSec. After receiving a third requestto connect to the SON from a third node in a third cloud, a secondconnection is created to connect the first node in first cloud to thethird node in third cloud. Similarly, a third connection is built toconnect the second node in second cloud to the third node in thirdcloud. It should be noted that the connections could be logicalpoint-to-point connections.

FIG. 1 is a block diagram 100 illustrating a network having anorchestrator able to manage and launch a SON between clouds inaccordance with one embodiment of the present invention. Diagram 100includes network or clouds 102-104, private cloud 106, and public cloud108. Note that the terms “network” and “cloud” can be usedinterchangeably to indicate a group of hardware and/or software devicesconnected with each other to perform a networking function(s). Cloud104, which can be either a private cloud or public cloud, contains orhosts orchestrator 112. Orchestrator 112, in one aspect, is coupled tovarious users 124-130 via one or more clouds and/or networks such ascloud 102. It should be noted that the underlying concept of theexemplary embodiment(s) of the present invention would not change if oneor more blocks (or devices) were added to or removed from diagram 100.

A cloud is cloud computing which includes a cluster of servers residingin the cloud. The servers in the cloud are able to support or hostmultiple virtual machines (“VMs”) running simultaneously. Cloudcomputing basically uses various resources including hardware, firmware,and software to deliver computing service. A benefit of using a cloud isthat it shares resources with other users so that resources can be usedmore efficiently. Another benefit of using a cloud is that it is able todynamically reallocate resources on demand.

A cloud can be a private cloud, a public cloud, or a hybrid cloud. Aprivate cloud such as cloud 106 is operated for a purpose of anindividual corporation, organization, and/or entity. The private cloud,in one example, can provide cloud-computing services over a network.Note that a private cloud can be managed or hosted internally,externally, or both. Cloud 106, for example, includes a set of servers114 capable of virtualizing various assigned operations using a group ofVMs 116.

A public cloud such as enterprise public cloud 108 that is open to thepublic providing computing services over a communication network. Apublic cloud, which is also known as community cloud, can be free orbased on a fee schedule in exchange of clouding service. For example,exemplary public cloud service providers can be Amazon web services(AWS)™, Microsoft™, Apple™, and/or Google™ and are able to host servicesacross the Internet. Enterprise public cloud 108, in one example,includes an array of servers capable of hosting and supporting a set ofVMs 118 running simultaneously.

Hybrid cloud, in one example, is a combination of multiple cloudsincluding private and public clouds. In an alternative example, a hybridcloud includes VMs as well as physical machines in one or more clouds.Hybrid cloud is able to host or support a set of VMs as well as physicalmachines operating simultaneously.

One advantage of using a cloud operating multiple VMs instead ofhardware is that some or a portion of traditional dedicated hardwaredevices such as routers and switches may not be required to build anetwork. Alternatively, a cloud can also combine VMs with existinghardware devices to optimize the performance of VN.

Orchestrator 112, in one aspect, arranges, coordinates, and manages oneor more VNs based on users' requests. In addition to virtualization,orchestrator 112 is able to provide other network related functions,such as provisioning, workflows, flexible resource allocation, billing,metering, accounting, policies, and user interfaces. To improve networkperformance, orchestrator 112, in one embodiment, is able to scale up orscale down based on demand based on the performance of VN. The terms“orchestrator,” “network orchestrator,” and “orchestrator of network,”mean the same apparatus and they can be used interchangeably.

A VM is a software implementation of a particular computer system thatprocesses tasks like a real physical machine. For instance, VM can beconfigured to execute instructions in a way that follows the emulatedcomputer architecture. A server or a cluster of servers containingspecialized hardware and software may be used to provide a VMenvironment that allows multiple VMs to be operated simultaneously. VMincludes system virtual machines and process virtual machines. Thesystem virtual machine includes a set of functions operating based on anoperating system. The process virtual machine is able to execute aprogram based on platform-independent program execution environment.Instance means a VM configured to execute program based on the emulationof a real machine or apparatus.

Private cloud or private network cloud 106 provides network services toa group of remote users across a network. In one aspect, private networkcloud 106 is configured to contain a group of servers 114 capable ofsupporting multiple VMs 116 running at the same or substantially thesame time. To communicate with orchestrator 112, private cloud 106 usesat least one Engreen™ host manager (“ehm”) 117 which can be placed inone of servers 114 to communicate with orchestrator 112.

Public network cloud or enterprise public cloud 108, which is coupled toprivate network cloud 106 via orchestrator 112, is configured to providecloud-computing service to remote users based on applications. Based ona requested or desired or constructed VN, a public network cloud 108 maybe selected or chosen to host the requested VN. The requested VN issubsequently launched in public network cloud 108. Public network cloud108 is able to host and execute VN(s) using various VMs 118 based on theinput from user, orchestrator, or both. To communicate with orchestrator112, public network cloud 108 uses a cloud application-programminginterface (“API”) 122 to facilitate communication between orchestrator112 and public cloud 108. A cloud API or APIs, in one example,facilitate establishing VNs.

Orchestrator 112, in one embodiment, communicates with users 128-130coupled to orchestrator 112 directly via cloud 104 and users 124-126coupled to orchestrator 112 via a cloud 102. Some users such as user 124are connected to orchestrator 112 via a wireless network. Orchestrator112 is able to manage VMs 116-118 located in clouds 106-108 in responseto input from remote users such as user 124 or user 130.

Orchestrator 112, in one embodiment, includes multiple dashboards, notshown in FIG. 1, wherein the dashboards are used to communicate withsubscribers or users 124-130 via one or more networks. For example,orchestrator 112 is able to post a set of icons on the dashboards tofacilitate user input. The icons, in one embodiment, are templatesrepresenting virtual components and/or real network devices. With inputfrom one or more subscribers or users 124-130, orchestrator 112 is ableto assist a subscriber to establish a VN based on selected templates viadashboard(s). It should be noted that additional private clouds and/orpublic clouds may be added in diagram 100. For example, multiple cloudscontaining different sets of VMs and physical machines may be selectedby orchestrator to launch a selected VN. One advantage of using anorchestrator to manage VNs is that the orchestrator may allow apredefined group of subscribes to clone an established VN.

To facilitate point-to-point connections between components situated indifferent clouds, a SON such as SON 132 can be established. SON 132, inone embodiment, is an overlay network capable to provide directconnection between server 114 in cloud 106 and VM 118 in cloud 108. Inone aspect, SON 132 is created based on a network security protocol suchas IPSec overlaying an existing Internet link. For example, SON 132 isestablished over the existing network between links 136-138 and cloud104. A function of SON 132 is to cause two connected end devices as theyare logically direct-connected.

An overlay network can be considered as a communication network or acomputer network that is established on the top of another network.Nodes in the overlay network are considered as being connected byvirtual or logical links. Each virtual or logic link may correspond to apath that may travel through multiple physical connections through thephysical or underlying network. In one embodiment, a SON is based on theoverlay network that resides on top of another existing network such asthe Internet.

A virtual appliance is a predefined VM and is able to run on a virtualmachine monitor or platform such as a hypervisor. A hypervisor is acombination of computer software, firmware or hardware that is able tohost and run VMs. For example, a virtual appliance allows a user to runvirtual applications without installation and/or configuration of thevirtual machine platform. An advantage of sharing a template of VN isthat it allows a group of users to work on a similar network for thesame as well as different tasks.

To create a seamless SON, a user can select a SON icon on a dashboardmanaged by orchestrator 112. The SON icon provides an option to a userbefore a VN is instantiated via the virtual network management (“VNM”)framework. Once SON 132 is created, servers that have been added to theservice as compute nodes can be added to SON 132. After the initialsetup, SON 132 is available for selection as a communications channelbetween clouds. When SON connects to two or more network components,orchestrator 112 automatically sets up the secure overlay network suchthat the network instances can communicate with each other as if theyare directly connected. It should be noted that SON is applicablebetween public and private clouds 106-108, public and public clouds(e.g., Amazon & Rackspace), or private and private clouds (e.g., two (2)different corporate datacenters located in different locations).

An advantage of using SON is that orchestrator allows users to launch aSON for facilitating communication between clouds without interventionfrom administrator, firewall changes, manual configuration, and thelike. It should be noted that automation of SON launch conservesresources such as manual operation and human interaction whereby the SONenhances overall network performance.

FIG. 2 is a block diagram illustrating an exemplary orchestrator havinga dashboard capable of managing SON in accordance with one embodiment ofthe present invention. Diagram 200 shows a network including anenterprise private cloud 202, orchestrator 204, and dashboard 212.Dashboard 212, in one aspect, resides online which can be accessed via abrowser 206. A physical machine such as system 220, in one example, canbe coupled to cloud 202 as part of cloud 202. It should be noted thatthe underlying concept of the exemplary embodiment(s) of the presentinvention would not change if one or more blocks (or devices) were addedto or removed from diagram 200.

Orchestrator 204, in one embodiment, includes an application server 214,web server 216, database 218, and SON manager 230. Orchestrator 204 maybe hosted by a private, public, micro, or hybrid cloud. In one example,orchestrator 204 can be hosted by cloud 202. Alternatively, anotherprivate or public cloud may be used to host orchestrator 204.Application server 214 is used to communicate with enterprise cloud 202via network connection 224. Connection 224 can be a wired, wireless, ora combination of wired and wireless network connection. A function ofapplication server 214 is to remotely control or manage VN(s) and/orSON(s) running at cloud 202 via ehm 210. Ehm 210, which may be residingin one or multiple servers 208, is able to report VN status toapplication server 214 and receives instruction(s) from applicationserver 214.

Web server 216, in one embodiment, is used to communicate with user(s)or subscriber(s) via dashboard(s) 212. In one aspect, Web server 216 iscapable of selectively posting icons or templates on dashboard(s) via awired or wireless connection 226. When a user or subscriber logs intoorchestrator 204 via a web browser such as browser 206, dashboard 212will display various predefined icon images including a SON option. Afunction of dashboard 212 is that it allows a subscriber to pick andchoose virtual devices represented by the icons to build a unique orapplication specific VN. Alternatively, dashboard 212 may also offer anopportunity for a user or subscriber to clone an existing VN.

SON manager 230, which can be hardware, software, firmware, or acombination of hardware, software, and firmware, is configured tofacilitate launching and maintaining an overlay network for networkcommunication. For example, SON manager 230 may include a SON table, notshown in FIG. 2, wherein the table records or maps one or more overlaynetworks. Depending on the applications, an active SON may be createdbased on secure, automatic, and/or dynamically overlaying acrossmultiple clouds via an existing communication network. Clouds, forinstance, can be located at different geographical locations. A functionof SON manager 230 is to provide a method or procedure to dynamicallycreate and manage one or more SONs over one or more existing networksacross several clouds.

Orchestrator 204, which can also be referred to as network orchestrator,network manager, and/or orchestrator of networks, is able to managevirtual devices as well as physical devices. Orchestrator 204 can alsoprovide automatic scaling in response to the demand and/or execution ofVN(s). An advantage of using an orchestrator is that it providesautomatic convergence as well as leveraging resources in differentphysical locations.

Cloud 202 is similar to cloud 106, shown in FIG. 1, except that cloud202 is coupled to physical machine 220. In one example, cloud 202 is aprivate cloud operated by an entity. The entity builds a unique VN totest its network device that may be installed in physical machine 220.After a provisioning process, orchestrator 204 facilitates building arequested VN that integrates physical machine 220 as a part of VN inaccordance with the subscriber's request. Once a desirable SON is builtor established, other components are allowed to join in the SON oncesuch components are verified and authenticated.

An advantage of providing a SON option by dashboard 212 is that itallows other users or subscribers to automatically launch or join SONwithout cumbersome process and administrators' interaction.

FIG. 3 is a block diagram 300 illustrating an exemplary dashboard ableto facilitate launch and manage SON in accordance with one embodiment ofthe present invention. Diagram 300 includes clouds 102-108, orchestrator112, and dashboard 308. Dashboard 308, in one embodiment, includes atoolbar 306, template 302, and pull-down menu 304. Toolbar 306 listsvarious buttons representing various functions such as home button andtemplate 302. It should be noted that the underlying concept of theexemplary embodiment(s) of the present invention would not change if oneor more blocks (or devices) were added to or removed from diagram 300.

Pull-down menu 304 illustrates multiple icons 310-322 representingvarious virtual or real network related devices (or components) whentemplate 302, for example, is clicked. Menu 304 lists various icons,such as tower 310, router 312, rack 314, network device 316, cloud 318,connection 320, and/or SON option 322. SON option 322 can also beconfigured as a button or icon as tower 310 or router 312. A subscriberor user can selectively pick and choose any icons to build a desirablevirtual network. Once a set of icons is selected, orchestrator willselect one of clouds 102-108 to launch the selected VN. Depending on theapplications, orchestrator 112 may scale up or down depending on thedemand of computing power in accordance with the selected VN.

An advantage of providing SON option on dashboard 308 is that it allowsa user to select SON option before the launch of a desirable VN.

FIG. 4 is a block diagram 400 illustrating exemplary clouds connectedvia a SON in accordance with one embodiment of the present invention.Diagram 400 includes orchestrator 204 and two private clouds 402-404which are interconnected via a virtual private network (“VPN”) 408. VPN408, in one example, can be a private network, public network, or acombination of public and private network. It should be noted that theunderlying concept of the exemplary embodiment(s) of the presentinvention would not change if one or more blocks (or devices) were addedto or removed from diagram 400.

VPN 408 is capable of transporting data between clouds 402-404 usinglinks and/or channels 406. VPN 408 may include one or more networks suchas the Internet and/or wide area network (“WAN”) to provide networkcommunications. VPN, in one instance, includes proxy servers to coverand to improve network services. In one embodiment, SON 480 isestablished over VPN 408 providing point-to-point connection betweennode 409 and node 440. A node, in one example, includes server(s),VM(s), physical network device(s), or a cluster of physical devices andVMs.

Cloud 402 includes multiple functional blocks or nodes such as servers409-411 wherein server 409 is further connected to router 412, database416, and controller 418. Similarly, while server 410 is connected torouter 422, database 426, and controller 428, server 411 is coupled torouter 432, database 436, and controller 438. Alternatively, cloud 402can be configured to include routers 409-411 wherein each router is ableto launch and maintain multiple VMs. For example, router 409 maintainsVM 412 as virtual server, VM 416 as virtual database, and VM 418 asvirtual controller.

It should be noted that routers, databases, servers, and/or controllerscan be virtual machines, physical machines, and/or a combination ofvirtual machines and physical machines. Cloud 402, for example, maycontain additional components, such as routers, switches, hubs, servers,databases, and the like. Depending on the applications, components ordevices such as routers and servers can be dynamically added or removedon demand.

Servers 409-411 are interconnected by a set of internal links 472. Inone example, internal network 470 couples an edge I/O (input and output)port 476 of cloud 402 to nodes 409-411. Internal network 470, in oneexample, encompasses a cluster of links 472 used for connections. Itshould be noted that internal links 472 and network 470 could bevirtual, physical, or a combination of virtual and physical connections.

Cloud 404, which is similar to cloud 402, includes multiple functionalblocks or nodes such as servers 439-441 wherein server 439 is connectedto router 442, database 446, and/or controller 448. Server 440 isconnected to router 452, database 456, and controller 458. Server 441 iscoupled to router 462, database 466, and controller 468. In analternative embodiment, cloud 404 is configured to include servers439-441 wherein each server is able to manage multiple VMs. For example,server 439 maintains VM 442 as virtual server, VM 446 as virtualdatabase, and VM 418 as virtual controller.

Servers 439-441 are interconnected by a set of internal links 473. Inone example, an internal network 471 is used to facilitate connectionsbetween links 473 with edge I/O port 478 of cloud 404. It should benoted that internal links 473 and network 471 can be virtual, physical,or a combination of virtual and physical connections.

In one embodiment, the communication network illustrated by diagram 400shows a SON 480 configured to provide point-to-point connection betweennode 409 and node 440. While nodes 409-411 reside in cloud 402 and nodes439-441 reside in cloud 404, SON 480 is established over existing VPN408. In one aspect, orchestrator 204 is used to control and maintain SON480.

Orchestrator 204, which is coupled to clouds 402-404, is able toestablish a point-to-point connection between the I/O port of a firstserver in cloud 402 and I/O port of a second server in cloud 404 inaccordance with a network security protocol. In one embodiment, thenetwork security protocol is IPSec that is capable of buildingpoint-to-point connections based on an existing network.

Diagram 400 may further include a third private cloud, not shown in FIG.4, configured to provide network services to users. Orchestrator 204 isable to generate a second point-to-point connection between the I/O portof the first server in cloud 402 and an I/O port of a third server inthe third private cloud. To provide a SON, orchestrator 204 is able togenerate a second point-to-point connection between the second I/O portof the second server in cloud 404 and the third I/O port of the thirdserver in the third private cloud as well as a third point-to-pointconnection between the first I/O port of the first server in cloud 402and third I/O port of the third server in the third private cloud.Orchestrator 204 is able to implement SON 480 over an existing networkor VPN 408 to establish point-to-point connections in accordance withIPSec.

An advantage of using SON is that SON allows a user to test a desirablenetwork that could span across one or more cloud boundaries. Forexample, various virtual and physical devices located in differentlocations can be connected using a secure and automated overlay network.SON, in one embodiment, allows the secure and seamless communicationbetween the devices using point-to-point (or end-to-end) connections (orlinks). It should be noted that an overlay network can be createdautomatically when the network is launched. Orchestrator 112 is alsocapable of tearing or terminating an existing SON when it is no longerneeded.

FIG. 5 is a block diagram 500 illustrating an exemplary networkconfiguration having multiple clouds coupled with SON in accordance withone embodiment of the present invention. Diagram 500 includes clouds502-508, orchestrator 112, and VPN 408, wherein clouds 502-508 aresituated in geographically different locations. For example, cloud 502may be in San Jose and cloud 504 is in Bangalore. While cloud 508 is inBeijing, cloud 506 is an Amazon™ public cloud situated in Seattle.Clouds 502-508 are connected by VPN 408 via channels 552-558 throughedge I/O ports 572-578. It should be noted that the underlying conceptof the exemplary embodiment(s) of the present invention would not changeif one or more blocks (or devices) were added to or removed from diagram500.

Cloud 502 includes multiple nodes such as nodes or servers 530-534wherein each node further includes one or more VMs, physical devices,and/or a combination of VM and physical device. For example, node 530,which can be a server, host, switch, hub, et cetera, includes multiplecomponents 536 connected by a set of internal links 537. Similarly,Cloud 504 includes nodes or servers 540-544 wherein each node furtherincludes one or more VMs, physical devices, and/or a combination of VMand physical device. For example, node 540, which can be a server, host,switch, hub, et cetera, includes multiple components 546 connected by aset of internal links 547.

Also, cloud 506 includes nodes or servers 510-514 wherein each nodefurther includes one or more VMs, physical devices, and/or a combinationof VM and physical device. For example, node 510, which can be a server,host, switch, hub, et cetera, includes multiple components 516 connectedby a set of internal links 517. Similarly, Cloud 508 includes nodes520-524 wherein each node may further includes one or more VMs, physicaldevices, and/or a combination of VM and physical device. For example,node 520, which can be a server, host, switch, hub, et cetera, includesmultiple components 526 connected by a set of internal links 527.

A communication network or VPN 408 is used to link clouds 502-508together via connections 552-558. Connections 552-558 are employed tolink I/O ports 572-578 of clouds 502-508 for information transmission.In one embodiment, a SON is established over VPN 408 to providepoint-to-point connections. For example, I/O port 538 of node 530 can beconnected to I/O port 548 of node 540 using point-to-point connections564-566 established over existing VPN 408 using SON. Similarly, I/O port538 of node 530 can be connected to I/O port 518 of node 510 usingpoint-to-point connections 564 and 562 established over existing VPN 408using SON. Also, I/O port 528 of node 520 can be connected to I/O port548 of node 540 and I/O port 538 of node 530 wherein point-to-pointconnections 566-568 are used to link between ports 528 and 548, andpoint-to-point connection 564 and 568 are used to link between ports 528and 538 of node 530.

In one embodiment, orchestrator 112 is able to communication with nodesdirectly using links 560 to facilitate building a SON. A networksecurity protocol may be used to build an overlay network over anexisting network. In one embodiment, the network security protocol isIPSec. When SON is established, a full-mesh connection between selectednodes is generated.

During an exemplary operation, orchestrator 112 is able to present adashboard via a communication network to a user or subscriber whereinthe dashboard displays an option of creating a SON. A first selectionrequesting SON such as SON 570 is received for point-to-pointconnections from a first virtual server 530 in a first cloud 502 overthe communication network 408. After receiving a second selectionrequesting SON 570 from a second virtual server 540 in a second cloud504 over the communication network such as VPN 408, a firstpoint-to-point connection 564-566 between first virtual server 530 andsecond virtual server 540 is established in accordance with SON 570using a network security protocol such as IPSec. After receiving a thirdselection requesting SON 570 from a third virtual server 520 in a thirdcloud 508, a second point-to-point connection 566-568 between secondvirtual server 540 in second cloud 504 and third virtual server 520 inthird cloud 508 as well as a third point-to-point connection 564-568between first virtual server 530 in first cloud 502 and third virtualserver 520 in third cloud 508 are established in accordance with SON570.

Upon establishing SON 570 using point-to-point connections 562-568connecting nodes 510-540, a full-mesh network is generated. An advantageusing a mesh network for a SON is that each node such as node 510 isdirectly, at least logically, connected to other nodes such as nodes520-540 even though the other nodes are located in different clouds.When two nodes are directly connected, the communication between the twonodes will be easier and more robust. In addition, existing networkingprotocols for point-to-point connection become available to nodes thatare connected in the mesh network.

FIG. 6 is a logic block diagram 600 illustrating an exemplary networkconnected by a point-to-point mesh configuration using SON in accordancewith one embodiment of the present invention. Diagram 600 includes nodes510-540 and point-to-point connections 602-614. Each node is directlyconnected to the rest of nodes within the SON in a full-meshconfiguration. For example, node 510 is directly connected to node 530via connection 602 and node 520 via connection 608. Also, node 510 isconnected to node 540 via connection 604. Similarly, node 540 isdirectly connected to node 530 via connection 606 and node 520 viaconnection 614. Also, node 540 is connected to node 510 via connection604. In one aspect, every node in the mesh network is directly connectedto all other nodes in the network.

The exemplary aspect of the present invention includes variousprocessing steps, which will be described below. The steps of the aspectmay be embodied in machine, router, or computer executable instructions.The instructions can be used to create a general purpose or specialpurpose system, which is programmed with the instructions, to performthe steps of the exemplary aspect of the present invention.Alternatively, the steps of the exemplary aspect of the presentinvention may be performed by specific hardware components that containhard-wired logic for performing the steps, or by any combination ofprogrammed computer components and custom hardware components.

FIG. 7 is a flowchart 700 illustrating an exemplary process ofestablishing SON across cloud boundaries in accordance with oneembodiment of the present invention. At block 702, a process able tolaunch and maintain SON is capable of receiving a first request from adashboard managed by an orchestrator for establishing SON. SON is ableto facilitate a point-to-point connection from a first node in a firstcloud over a communication network. In one aspect, a dashboard managedby orchestrator interacts with the user for facilitating options or userselections before launching a VM. For example, an option selected by afirst user is received via a dashboard which is facilitated by theorchestrator for launching VN.

At block 704, the process is able to receive a second request forconnecting to the SON from a second node in a second cloud over thecommunication network. In one example, a SON selection is received froma dashboard managed by the orchestrator from a second user via a nodefrom a public cloud.

At block 706, the process establishes a first connection between a firstport of the first node and the second port of the second node using anetwork security protocol such as IPSec. After receiving a third requestfor connecting to the SON from a third node in a third cloud over thecommunication network, a second connection is established between thefirst port of the first node and the third node of the third cloud. Athird connection is also established or created between the second nodeof the second cloud and the third node of the third cloud. As morerequests are received for adding a cloud to the SON, a new connection iscreated from the new node of the new cloud to each existing node of eachexisting cloud to form the full-mesh. Note that IPsec is able to build asecure packet exchange tunnel at IP layer.

While particular embodiments of the present invention have been shownand described, it will be obvious to those of ordinary skills in the artthat based upon the teachings herein, changes and modifications may bemade without departing from this exemplary embodiment(s) of the presentinvention and its broader aspects. Therefore, the appended claims areintended to encompass within their scope all such changes andmodifications as are within the true spirit and scope of this exemplaryembodiment(s) of the present invention.

What is claimed is:
 1. A communication network having a plurality ofvirtual machines (“VMs”), comprising: a first private cloud configuredto provide network services to a plurality of users, the first privatecloud comprising a first edge input and output (“I/O”) port into and outof the first private cloud, the first private cloud further comprising afirst server inside the first private cloud, the first server having afirst interior I/O port; a public cloud configured to provide cloudcomputing service to users, the public cloud comprising a second edgeI/O port into and out of the public cloud, the public cloud furthercomprising a second server inside the public cloud, the second serverhaving a second interior I/O port; a communications network connectingthe first edge I/O port of the first private cloud to the second edgeI/O port of the public cloud; an orchestrator coupled to the firstprivate cloud and the public cloud, wherein the orchestrator isconfigured to establish a first point-to-point connection laid over thecommunications network for logically direct communication between thefirst interior I/O port of the first server inside the first privatecloud and the second interior I/O port of the second server inside thepublic cloud in accordance with a network security protocol, wherein theorchestrator comprises a computer processor; and a second private cloudcoupled to the first private cloud and configured to provide networkservices to a plurality of users, wherein the orchestrator is configuredto generate a second point-to-point connection between a first I/O portof the first server and a third I/O port of a third server in the secondprivate cloud, wherein the orchestrator is configured to generate athird point-to-point connection between a second I/O port of the secondserver in the public cloud and the third I/O port of the third server inthe second private cloud.
 2. The network of claim 1, wherein theorchestrator is configured to establish a secure overlay network (“SON”)over an existing network to establish point-to-point connections inaccordance with Internet Protocol Security (“IPSec”).
 3. The network ofclaim 2, wherein the orchestrator is configured to utilize a pluralityof icons on dashboards, wherein one of the plurality of icons is aselectable option for establishing SON.
 4. The network of claim 3,wherein the orchestrator is configured to manage a cluster ofpoint-to-point links generated in accordance with SON.
 5. The network ofclaim 1, wherein: the first edge I/O port of the first private cloud isdisposed between the first interior I/O port of the first server in thefirst private cloud and the communications network, and the second edgeI/O port of the public cloud is disposed between the second interior I/Oport of the second server in the public cloud and the communicationsnetwork.
 6. The network of claim 1, further comprising a dashboardcoupled to the orchestrator and configured to interact with a user forfacilitating a plurality of user selections before launching a virtualmachine (“VM”).
 7. The network of claim 1, further comprising adashboard managed by the orchestrator and configured to receive arequest from a user for establishing a secure overlay network (“SON”).8. The network of claim 1, wherein the orchestrator provides a dashboardallowing a user to select a secure overlay network (“SON”) selection toestablish a secure overlay network (“SON”) between the first server andthe second server.
 9. The network of claim 1, further comprising adashboard managed by the orchestrator and configured to provide anoption of creating a secure overlay network (“SON”) to a user via thecommunication network.
 10. A method for generating network connectionsbetween cloud computing managed by an orchestrator, comprising:presenting a dashboard including an option of creating a secure overlaynetwork (“SON”) to a user by the orchestrator via a communicationnetwork, wherein the orchestrator comprises a computer processor;receiving over the communication network a first selection requesting afirst SON for a point-to-point connection from a first interior inputand output (“I/O”) port of a first virtual server inside a first cloud;receiving over the communication network a second selection requestingthe first SON and a second SON from a second interior I/O port of asecond virtual server inside a second cloud; establishing a firstpoint-to-point logically direct connection laid over an existing networkbetween the first interior I/O port of the first virtual server and thesecond interior I/O port of the second virtual server in accordance withthe first SON utilizing a network security protocol, wherein theexisting network connects a first edge I/O port of the first cloud to asecond edge I/O port of the second cloud; receiving a third selectionrequesting the second SON from a third virtual server in a third cloudand establishing a second point-to-point connection between the secondvirtual server in the second cloud and the third virtual server in thethird cloud in accordance with the second SON utilizing InternetProtocol Security (“IPsec”); and receiving a fourth selection requestingthe first SON and the second SON from a fourth virtual server in afourth cloud and establishing a third point-to-point connection betweenthe fourth virtual server in the fourth cloud and the third virtualserver in the third cloud in accordance with the second SON utilizingInternet Protocol Security (“IPsec”).
 11. The method of claim 10,further comprising establishing a fourth point-to-point connectionbetween the fourth virtual server in the fourth cloud and the firstvirtual server in the first cloud in accordance with the first SONutilizing Internet Protocol Security (“IPsec”).
 12. The method of claim11, further comprising establishing a fifth point-to-point connectionbetween the fourth virtual server in the fourth cloud and the secondvirtual server in the second cloud in accordance with the first and thesecond SON utilizing Internet Protocol Security (“IPsec”).
 13. Themethod of claim 10, further comprising establishing a thirdpoint-to-point connection between a first server and a third server viaIPsec.
 14. The method of claim 10, wherein: the first edge I/O port ofthe first cloud is disposed between the first interior I/O port of thefirst virtual server in the first cloud and the communication network,and the second edge I/O port of the second cloud is disposed between thesecond interior I/O port of the second virtual server in the secondcloud and the communication network.